NL8600684A - COMPLETE TRANSPARENT PROJECTION SYSTEM WITH INCREASED LIGHT BEAM. - Google Patents

Description

* fc 4 PHN 11,675 1 N.V. Philips' Incandescent Lamp Factories in Eindhoven.

Compact rear projection system with skewed light beam.

The invention relates to a rear projection system comprising a rear projection screen f at least one image source with an associated projection lens system, and at least one mirror intended for folding the light path.

In a rear projection system, the primary image supplied by an image source is projected on a first side, indicated by rear side, of the projection screen. This image can be seen by a spectator who is located on the second side, called front of the screen.

10 A rear projection screen affects both the average direction of the emerging light, as well as the distribution of that light in the spectator room. These functions can be performed by separate optical elements, but both functions can also be combined in the same element. For the purposes of the present invention, the term "projection plate" is intended to mean that element of the projection screen in which the light distribution takes place, irrespective of whether or not the same element has a function with regard to recording the average direction of the exiting light .

Transparency projection systems comprising one image source in the form of a cathode ray tube for black-and-white reproduction, or three such image sources for color reproduction, are used for displaying a video program in a format considerably larger than the format achievable with a conventional 25 television picture tube.

An image source used in the projection system can also be constituted by a light source and a transparent placed in front of it in the form of a slide or film. It is also possible for an image source to be constituted by a light source and an electronically controllable flat display device, composed of a matrix of image cells which, depending on the electronic signal, reflect or absorb light, or transmit or absorb light, respectively. With a - - * 'M j «j

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PHN 11.675 2 such flat display device, for example, video images can be displayed. As a final example of a possible image source, the electro-optical converter is described herein in British Patent No. 1,387,712.

A drawback of rear projection systems is the large volume of the housing in which the projection screen, the image source (s) and the (de) projection lens system (s) are housed. Slightly depending on the dimensions of the image source and the number and placement of the mirrors, the volume of this housing at a screen diagonal of 114 cm (45 inches) is comparable to that of a book or crockery cabinet.

U.S. Patent No. 4,491,872 describes a rear projection system the housing of which is extendable. The image source, the electronic circuits and the power supply are housed in an immovable lower part of the device. The rear projection screen and one of the mirrors are mounted in the extendable part. When the device is not in use, the extendable part, with the projection screen and mirror, is slid into the lower fixed part. The device then only occupies a relatively small volume. During use, the extendable part is pushed up and an image or scene can be displayed on the screen.

Although in retracted condition this system has a noticeably more compact appearance than a similar device in which the screen is in a fixed position, the space requirement of the extendable device is not substantially less. The occupied floor space is the same in both cases. The space above the retracted device can only be used to a very limited extent for other purposes, because these must be kept free for the projection screen and the mirror.

The second drawback is to mention the construction of the extendable device. A large number of additional parts are required, such as a drive motor, a mechanical transmission device, etc., which makes the device more expensive and heavier.

The aim of the present invention is to provide a rear projection system which takes up a considerably smaller volume compared to conventional systems. To this end, a PHN 11.675 3 has a rear projection system according to the invention characterized in that the major axis of the light beam of each image source intersects the rear face of the projection screen at an angle of the order of a few tens of degrees with the normal in this plane.

The invention is based on the insight that by a suitable choice the angle of incidence of the light beam from an image source on the projection screen, the folding mirror can be placed in such a way that the cabinet volume is reduced while the optical properties of the screen with respect to the light distribution are nevertheless the 10 spectators' space can be preserved.

A preferred embodiment of a rear projection system according to the invention is characterized in that the angle made by the main axis of the light beam of an image source with the normal on the rear face of the projection screen is approximately 30 °. At an angle of 30 °, the volume reduction is considerable, while the measures mentioned below to be taken to compensate for the effects of the skewed light on the light distribution in the spectator room are easily practicable and involve few drawbacks.

A rear projection system according to the invention is further characterized in that the projection screen comprises, in addition to a projection plate, a prism plate, consisting of a number of truncated prisms joined together into a plate, the plate of which forms the rear side of the projection screen, and which plate ensures that the The light beam from the image source is deflected in the direction of the normal on the projection plate.

It should be noted that U.S. Patent No. 4,003,080 discloses a video program display device using a light beam falling at an angle on the screen and containing a correction plate to extend a light beam falling at an angle forwardly forward. make the screen step.

However, the said patent relates to a laser scanning system in which an image is written with an intensity-modulated beam 35 and not to a projection device. The correction plate consists of a Fresnel lens or a series of narrow mirrors arranged one above the other and is not a S i PHN 11.675 4 prism plate.

A first embodiment of a rear projection system according to the invention is characterized in that the prism plate is composed of a number of prisms with equal top angle and orientation, and that for light incident parallel to the main axis of the light beam, the refraction angle at the rear of the prism plate is almost equal to the angle of refraction at the front. In this configuration, an apparent displacement of the image source to the axis of the projection screen is approximated as closely as possible with a relatively simple prism plate consisting of prisms of equal top angle and equal orientation. Furthermore, the light losses on the prism plate are minimal. On the one hand because, because of the small angle of the light beam with the normally on the refracting prism surfaces, reflection losses are small, on the other hand because in this configuration the loss of light because it falls on a third surface of a prism at the back of the plate is considerably less. is then with a one-sided prism plate, with the prisms at the back.

A second embodiment of a rear projection screen according to the invention is characterized in that the prism plate is composed of prisms whose top angle and orientation are different, the sub-beam emerging from each prism intersecting the normal on the projection screen in the center at a common point, and wherein for the sub-beam passing through each prism the angle of refraction at the rear of the prism plate is almost equal to the angle of refraction at the front.

This embodiment can be further characterized in that the common point where the sub-beams emerging from the prism plate seem to cut normally on the projection screen in the center lies behind the screen. In this configuration the image source is, as it were, superimposed on the projection screen.

The use of a prism plate consisting of identical and identically oriented prisms, because the apparent position of the projection lens varies in different parts of the screen, the result that the brightness in different parts of the image as perceived by the viewer can vary widely. exhibit. The viewer perceives this as dark bands at the top and bottom edge of the screen. The size of the effect depends on the light spreading effect of the projection plate. This disadvantage is eliminated by the said measure.

A rear projection screen usually contains a correction plate, for example a Fresnel lens, which depicts the pupil of the 5 projection lens in the spectator room. The divergent light beam from the image source becomes approximately parallel or converging towards the front. the audience space. This Fresnel lens can be integrated with the prism plate.

A further feature of the second embodiment of a rear projection screen according to the invention may be that the common point where the subbeams emerging from the prism plate intersect normally on the projection screen is in front of the screen. This makes a separate Fresnel lens in one direction superfluous. Optionally, this intersection point can be infinite, so that the sub-beams exit parallel to the main axis.

A third embodiment of a rear projection screen according to the invention is characterized in that a flat convex cylinder lens is arranged at the rear of each prism. This cylinder lens spreads the light from the image source 20 in the spectator space in the vertical direction, so that other measures for obtaining light distribution in the vertical direction, such as a diffuse scattering layer, can be omitted. The radius of curvature of the flat convex cylinder lens determines the vertical angle at which the light is scattered. The flat convex cylinder lenses can be manufactured simultaneously with the prism plate in the same process step.

A further feature of a rear projection system in accordance with the invention may be that at least one side of the prism plate is anti-reflective. Light loss due to reflection on the surfaces is reduced with this measure.

The invention will be further elucidated with reference to the drawing, in which figures 1a, 1b and 1c schematically show three embodiments of a known rear projection system, wherein the main axis of the light beam is perpendicular to the projection screen, figures 2a, 2b and 2c schematically show three embodiments of a * 7 * - PHN 11.675 6 rear projection system according to the invention, comparable to figures 1a, 1b and 1c, in which the main axis of the light beam makes an angle of 30 ° with the normal of the projection screen, figure 3 the indicates the location and operation of the prism plate 5, figures 4a, 4b and 4c show various possible embodiments of the prism plate, and figure 5 shows a prism plate with flat convex lenses mounted on the prism facets.

In the figures, reference characters, the last two digits of which are equal, are used to indicate like elements.

In Figure 1a, an image or scene is formed on the screen 111 of a cathode ray tube 110. The light beam emitted by this image source, the main axis of which is indicated at no. 115, is projected by mirrors 121 and 122 on the rear side of a rear projection screen 130 by the schematically indicated projection lens system 112. Instead of a single cathode ray tube 110 for black-and-white display, multiple cathode ray tubes with as many projection lens systems can also be used for color reproduction of an image or a scene. Any other form of an extensive image source can also be used. As an example, a light source is mentioned, and a transparent, for example a slide or film, to be used as the image source, placed between the light source and the lens system. It is also possible that the image source consists of a flat display device, composed of a matrix of image cells, which, depending on electronic signals, reflect or absorb light or transmit or absorb light, and a light source. The electro-optical converter mentioned in British Patent No.

1,387,712 can also be used as an image source. The image source (s), mirrors and the rear projection screen are housed in a housing 140.

Figures 1b and 1c show, by way of example, alternative configurations of rear projection systems, wherein the major axis of the light beam is also perpendicular to the rear projection screen (230 in Figure 1b, 330 in Figure 1c). In these examples, a projection lens system (212, 312) is shown, with a mirror (213, 313) incorporated therein (PHN 11,675), which in itself allows reduction of the housing (240, 340).

Figures 2a, 2b and 2c show three examples of rear projection systems according to the invention in which the main axis 5 (415, 515 and 615 in the three figures) of the light beam makes an angle of approximately 30 ° with the normal on the projection screen (430, 530, 630). The beam paths in Figures 2a, 2b and 2c are comparable to those in Figures 1a, 1b and 1c, respectively. A comparison of these figures shows that the systems according to the invention have a smaller volume.

The table below shows some characteristic dimensions of the various housings. In all cases, this is based on a screen whose diagonal measures 114 cm (45 inches), and whose aspect ratio is 3 by 4. For screens with a different size, the indicated sizes must be adjusted.

Version according to Dimensions Volume proj. distance figure Η x W x D (cm3) (dm'3) (cm) 20 1a 138 x 90 x 55 683 160 2a 140 x 90 x 40 504 140 lb 96 x 90 x 60 518 160 2b 103 x 90 x 45 417 170 1c 130 x 90 x 50 585 120 25 2c 97 x 90 x 50 437 120

As can be seen from the table, the volume reduction by applying the invention is about 20 to 25%.

This is realized by a smaller height or a smaller depth of the housing. A smaller width is not possible since it is determined by the size of the projection screen.

Figure 3 schematically shows a rear projection screen for use in a device according to the invention. The screen 730 35 includes a prism plate 731 and a projection plate 732. The projection plate 732 contains light-scattering elements which spread the light from the image source into the spectator room. The details of the * »PHN 11.675 8 projection plate 732 are determined by the requirements with regard to, among other things, the light distribution in horizontal and vertical direction, the color reproduction in case different image sources are used for different colors, the 5 brightness distribution over the screen, etcetera. A large number of possible embodiments for a rear projection screen have been described in the literature. The prism plate 731 deflects the light beam b from the image source, the main axis of which defines an angle Θ with the normal on the plate 731, such that the main axis of the emerging beam is almost perpendicular to the projection plate 732.

Figure 4a shows a detail of a first embodiment of the prism plate. This plate can be considered to be composed of an imaginary plan-parallel plate 833 on either side of which triangular light-refracting elements 834 and 835 are arranged, so that an element 834, or a part thereof, at the rear, is an opposite part of an element 835. together with the intermediate portion of the plane parallel plate 833 form a truncated prism. This prism plate can be regarded as a series of identical and identically oriented prisms. Some of these prisms 20 are indicated by dotted lines. The prisms are characterized by the angles α and 8 that make the breaking planes at the back and front with the plane of the imaginary plan-parallel plate, the sum of α and fi, denoted top angle ^, and the angle δ that the third plane of a prism with the normal on the 25 prism plate. Preferably, the prisms are oriented such that light incident parallel to the major axis of the light beam experiences a minimum deviation. This means that the angle of incidence 0 ^ on the rear facet of an element 834 is equal to the angle of exit 0U from the anterior facet of an element 835. By sliding the elements 30 834 and 835 relative to each other as shown in figure 4a a plate of less thickness can be realized.

The values of angles α, B, and δ, and their interrelationships are determined by the required refraction and the value of the refractive index of the material. For example, when the major axis of the incident light beam makes an angle Θ of 30 ° with the normal on the plane of the prism plate, the refractive index of the material of the prism plate is 1.5, and a minimum deviation is required for light that $ ? Λ. α · λ Ί Λ y .j,., V ·; . -i PHN 11.675 9 falls parallel to the main axis, then a value of 52 ° must be selected for the top angle lf, and 41 ° for the angles a and ö, 11 ° and 41 ° respectively. An optimal adjustment of the prisms then takes place at a value for the angle δ of 15 °.

The above-described configuration of a series of identical and identically oriented prisms does not cause the light emerging from the front face of the prism plate to appear to be one point behind the prism plate. As a result, the light emerging from the projection plate into the spectator room has a scattering characteristic which can show significant differences for different parts of the screen. This is perceived by the viewer as dark bands on the top and bottom of the image. The degree of the effect depends on the detailed construction of the projection plate. The said drawback can be overcome by adjusting the apex angle and the orientation of each prism so that the projection lens and the image source are placed, as it were, on the normal through the center of the projection screen.

Figure 4b shows a possible embodiment of the prism plate in which the sub-beam from each prism appears to intersect the optical axis of the projection screen at the same point behind the plate. Preferably, the angles of each prism are configured such that minimum deviation for each subbeam occurs. In figure 4b, 3 parts A, B and C can be distinguished that correspond to the center of the plate (B) and the two extremes (A and C). These signs are also provided in figure 3 for orientation.

At a projection distance of 120 cm and a screen height of 68 cm (this corresponds to a diagonal dimension of 114 cm and an aspect ratio of 3 by 4), the angles that the part beams make with the normal on the prism plate vary from 14 ° at A to 30 42 ° at C when the angle of the main axis of the beam to the normal on the plane of the prism plate is 30 °. Under these conditions, and with minimum deviation for each sub-beam and a refractive index of the material of 1.5, the angle α that the facets on the back of the prism plate make with the plane of the prism plate must have a gradient of 35 27 ° at A, via 11 ° in the middle (B), to -6 ° at C. The angle B should extend from 25 ° via 41 ° to 52 °.

A rear projection screen usually contains a separate PHN 11.675 10

Fresnel lens with which the pupil is tilted from the projection lens in the spectator room. In one direction, this Fresnel lens can be integrated into the prism plate by adjusting the refractive angles of each prism to the desired direction of a 5 Fresnel facet on site. Figure 4c shows an exemplary embodiment of a prism plate on which plate a Fresnel term is superimposed, so that no separate Fresnel lens in vertical direction is needed anymore in the remaining part of the rear projection screen. This plate is characterized in that each sub-beam is deflected by the corresponding prism in the prism plate to the same point on the optical axis of the projection screen, which point is located in front of the screen in the spectator space, for example at a distance of 2.5 m. other conditions are equal to the situation as described in figure 4b, the angle α goes from -6 ° at A 15 via 11 ° at B to 19 ° at C, and the angle Q from 17 ° via 41 ° to 52 °.

The point at which the sub-beams intersect the optical axis of the screen can be chosen at any desired distance from the screen, possibly indefinitely by adjusting the refractive angles of the 20 prisms.

The rear projection screen also contains elements that spread the light over the spectator space. These can be cylinder lenses arranged in the projection plate. Cylindrical lenses extending horizontally for light distribution in the vertical direction can be integrated with the prism plate by choosing not flat but convex prism facets on one side of the plate. This is illustrated in Figure 5 which shows a sketch of a portion of a prism plate in which such flat convex cylinder lenses 936 are integrated with the facets 934 at the rear of the prism plate. For a light spread over vertical angles between + 10 ° and -10 ° with a refractive index of the material of 1.5, the radius R of the cylinder lenses should be approximately 1.4 times the pitch S of the prism plate. Greater losses can occur due to reflection on the curved surfaces. To avoid this, the angle 35 making the incident light to the normal of the prism plate should be limited to a maximum of about 35 °. This means that, with the screen size and projection distance as assumed in the Λ Λ * - '= · 4 Q J' ·. ' ·; PHN 11.675 11 described examples the angle Θ that the main axis of the light beam makes with the normal on the prism plate must be limited to a maximum of about 20 °.

Claims (3)

1. A rear projection system comprising a rear projection screen, at least one image source with an associated projection lens system, and at least one mirror intended for folding the light path, characterized in that the main axis of the light beam of each image source intersects the rear surface of the projection screen at an angle of the order of a few tens of degrees with the normal in this plane. 2. A rear projection system according to claim 1, characterized in that the angle made by the main axis of the light beam of an image source with the normal on the rear face of the projection screen is about 30 °. A rear projection screen according to claim 1 or 2, characterized in that the projection screen comprises, next to a projection plate, a prism plate, consisting of a number of truncated prisms joined together into one plate, the plate of which forms the rear side of the projection screen, and which plate causes the light beam from the image source to be deflected in the direction of the normal on the projection plate. 4. A rear projection system according to claim 3, characterized in that the prism plate is composed of a number of equal and equally oriented prisms, and that for light incident parallel to the main axis of the light beam, the angle of refraction at the rear of the prism plate is almost equal at the angle of refraction at the front. A rear projection system according to claim 3, characterized in that the prism plate is composed of prisms whose apex and orientation are different, the sub-beam emerging from each prism intersecting the normal on the projection screen in the center at a common point, and wherein for the sub-beam passing through each prism, the angle of refraction at the rear of the prism plate is almost equal to the angle of refraction at the front. A rear projection screen according to claim 5, characterized in that the common point where the sub-beams emerging from the prism plate seem to intersect normally on the projection screen in the center is behind the screen. A rear projection screen according to claim 5, characterized in that the common point, where the sub-beams emerging from the prism plate: snijden · -i * “> PHN 11.675 13, intersect normally on the projection screen in the center, lies in front of the screen. 8. A rear projection screen according to claim 3, 4, 5, 6 or 7, characterized in that a flat convex cylinder lens is arranged at the rear of each prism. A rear projection system according to claim 3, 4, 5, 6, 7 or 8, characterized in that at least one side of the prism plate is anti-reflective. ^ Λ i w. Λ